KR101218007B1 - Detecting legacy powered device in power over ethernet system - Google Patents

Abstract

Provided are a system and method for the detection of a powered device in a Power over Ethernet (PoE) system. The PD probe circuit generates a detection signal supplied to the PD and determines the PD response signal generated in response to the detection signal. Based on the PD response signal, a control circuit determines a detection value for identifying the PD. In particular, the control circuit determines whether the PD is a device that satisfies the PoE standard when the detection value is within a predetermined first range, and the detection value is within a second predetermined range outside the first range. In this case, the PD is determined as a legacy device.

PoE, Power Sourcing Unit (PSE), Power Equipment (PD), Legacy PD

Description

Legacy Power Device Detection in Power Systems over Ethernet {DETECTING LEGACY POWERED DEVICE IN POWER OVER ETHERNET SYSTEM}

The present invention relates to a power supply system, and more particularly, to a circuit and a method for detection of a legacy power device in a Power over Ethernet (PoE) system.

In the past few years, Ethernet has become the most commonly used method in local area networks (LANs). The IEEE 802.3 group, the founder of the Ethernet standard, has expanded to a standard known as IEEE 802.3af, which is defined as powering over Ethernet cabling. The IEEE 802.3af standard defines a Power over Ethernet (PoE) system. The PoE system extends from a power sourcing device (PSE) to a power device (PD). It involves the transmission of power through unshielded twisted-pair (UTP) wiring. Traditionally, network devices such as IP phones, wireless LAN access points (APs), personal computers (PCs), and web cameras require two connections, namely a connection to a LAN and a power supply. did. The PoE system does not require additional outlets and wires to supply power to the network devices. Instead, power is supplied through the Ethernet cable used for data transmission.

As defined in the IEEE 802.3af standard, the PSE and PD are non-data entities that allow network devices to power and draw using the same generic cabling used for data transmission. entities). At this point, the PSE is a device that is electrically defined at the physical connection point with the cabling that provides power to the link. In addition, PSEs are typically associated with Ethernet switches, routers, hubs, or other network switch devices, or midspan devices. A PD is a device that draws power or requests power. PDs are associated with devices such as digital IP phones, wireless network APs, PDA or notebook computer docking stations, cell phone chargers, and HVAC (heating, ventilating, and air conditioning) thermostats. There may be.

The main functions of the PSE include: searching for links to find PD request power, optionally classifying PDs, powering the link when a PD is detected, monitoring power on the link, and It includes the ability to shut off power when power is no longer required or needed. The PD participates in the PD detection procedure by presenting a PoE detection signature defined by the IEEE 802.3af standard. The PD detection signature has electrical characteristics measured by the PSE, such as signal resistance in the range of 19 to 26.5 KΩ.

However, some PDs manufactured prior to the IEEE 802.3af standard approval do not have an IEEE 802.3af standard detection signature. Such PDs are considered legacy PDs. For example, some legacy PDs may use a large capacitor C and at least one diode as their PoE detection signal. In another legacy PD, data loopback may be used for its PoE detection signature. The data loopback includes a smaller capacitor C between wire pairs that are not used directly for PD detection.

Although it is desirable to power the legacy PD, the legacy PD is not detected in the normal PD detection process. Therefore, there is a need for a new PD detection method that can support the detection of legacy PDs.

The present invention provides a novel system and method for detecting a network powered device (PD) in a Power over Ethernet (PoE) system. According to one aspect of the present invention, a PD probe circuit generates a detection signal supplied to the PD and determines a PD response signal generated in response to the detection signal. do. Based on the PD response signal, the control circuit determines a detection value for identifying the PD. In particular, the control circuit determines whether the PD is a device that satisfies the PoE standard when the detection value is within a predetermined first range, and determines the PD if the detection value is within a second predetermined range outside the first range. It is determined as a legacy device.

According to one aspect of the invention, the control circuit determines whether the PD is a legacy device by comparing the detection value with a predetermined threshold detection value. That is, if the detection value is negative or less than the predetermined threshold value, the PD may be identified as being a legacy device. In this case, the predetermined threshold value is smaller than the minimum value of the first range.

According to a preferred embodiment of the present invention, the detection value may include a detection resistance value. If the detection resistance value is negative or less than the threshold resistance value, the control circuit may determine the PD as a legacy PD. The threshold resistance value may be less than a minimum signature resistance value defined according to the IEEE 802.3af standard.

The PD probe circuit may generate a first detection current, and generate a second detection current having a value smaller than the first detection current. The control circuit may detect the legacy PD when the first response voltage generated in response to the first current is less than the second response voltage generated in response to the second current.

Also, the control circuit may detect the legacy PD when the first response voltage is greater than the second response voltage. However, in this case, the difference between the first response voltage and the second response voltage is less than the preset threshold.

That is, the control circuit may detect the legacy PD when the detection resistance value defined by the first response voltage according to the difference between the second response voltages is negative or smaller than the predetermined threshold resistance value. In this case, the predetermined threshold resistance value is smaller than the minimum signature resistance value defined according to the PoE standard.

According to the method of the present invention, the following steps are performed to detect a powered device in a PoE supply system. The steps may include generating a detection signal supplied to the PD to determine a PD response signal; And when the detection value exists in the first predetermined range, based on the response signature with power, the PD determines that the device satisfies the PoE criterion, and the detection value is in the second predetermined range outside the first range. If present, characterized in that it comprises a power supply method for determining that the PD is a legacy PD.

The generating of the detection signal may include generating a first detection signal and generating a second detection signal smaller than the first detection signal. The legacy device detects when the detection resistance value defined by the difference between the first response signal generated in response to the first detection signal and the second response signal generated in response to the second detection signal is negative or less than a predetermined threshold resistance value. do.

Additional advantages and aspects of the present invention will become apparent to those skilled in the art through the following detailed description. In the above detailed description, embodiments of the present invention are shown and described through preferred embodiments for practicing the present invention. As will be described later, the present invention may be embodied in other embodiments without departing from the spirit of the invention, and several details thereof may be modified in various obvious respects. Accordingly, the drawings and descriptions should be regarded as illustrative in nature, not as limitative.

The following detailed description of embodiments of the invention may best be understood when read in conjunction with the accompanying drawings, in which features are best described rather than to compare related features. In order to show you.

1 is a block diagram illustrating a power device (PD) detection system in accordance with a preferred embodiment of the present invention.

2 illustrates a Norton equivalent circuit of a detection source.

3 is a flow diagram illustrating a control algorithm for controlling the operation of a legacy power device detection system.

Hereinafter, the present invention will be described with an example of detecting a legacy power device in a Power over Ethernet (PoE) system. The concepts described herein are applicable to recognizing any connectable power device that is powered on a power supply system.

1 is a simplified block diagram of a power device (PD) detection system 10 of the present invention in a PoE system. The PoE system includes a Power Sourcing Equipment (PSE) 12 and a PD 14 connectable to the PSE 12 via a link 16. At this time, an example of the link 16 is a 2-wire link defined in the IEEE 802.3af standard. The PD detection system 10 includes a detection source 18 and a controller 20 that can be arranged on the PSE 12.

The detection source 18 may be a force-current detection source that generates a detection current Idet supplied to the PD 14 and determines the generated voltage Vres in response to the detection current. Can be. The controller 20 may be a state machine or a microcontroller arranged on the PSE 12.

2 illustrates a Norton equivalent circuit of detection source 18. The detection source 18 includes a current source 22, a source resistance value Rsc connected in parallel with the current source 22, and a voltage monitor connected in parallel with the source resistance value Rsc ( 24).

In each step for detecting the PD 14, the detection source 18 generates a detection current Idlt corresponding to the detection voltage Vdet. In this case, the detection voltage Vdet is within a range of 2.8V to 10V defined in the IEEE 802.3af standard. The source resistance value Rsc may be in the range of 100 KOhm to 100 MOhm. The minimum current difference between the values of the detection current Idet generated for the other detection tests corresponds to the Vdet voltage difference of 1V.

The voltage monitor 24 determines the voltage Vres generated in response to the detection current Idet supplied to the probe target device. The detection resistance value Rdet of the PD 14 is determined as in the following equation.

Rdet = ΔVres / △ Idet

ΔIdet is the difference between the detection currents obtained in different tests, and ΔVres is the difference between the voltages generated in response to the respective detection currents.

3 is a flowchart illustrating a control algorithm executed by the controller 24. The controller 24 allows the PD detection system 10 to detect legacy PDs that do not have a detection signature in accordance with the IEEE 802.3af standard. That is, some legacy PDs may use a large capacitor (C) and at least one or more consecutive diodes as their PoE detection signature. For another legacy PD, data loopback may be used for its PoE detection signal. The data loopback includes a smaller capacitor C between wire pairs that are not used directly for detection.

After the PD detection process has started (step 102), the control unit 20 requests the detection source 18 to generate the detection current I ₁ . For example, 240 μA current can be generated. For example, after a preset latency equal to 160 ms, the detection source 18 allows the voltage monitor 18 to measure the voltage V _{1 that} develops in response to the current I ₁ supplied to the probe target device. Controlled (step 104).

Next, the controller 20 requests the detection source 18 to generate a detection current I ₂ having a value smaller than the detection current I ₁ . For example, the detection current I ₂ may be a value equivalent to 180 μA current. After a preset latency equal to 160 ms, the voltage monitor 24 is asked to measure the voltage V _{2 that} is generated in response to the current I ₂ supplied to the PD 14 (step 106).

Based on the measured response voltage values V ₁ and V ₂ , the controller 20 calculates the detection resistance Rdet of the PD 14 (step 108).

Rdet = (V ₂ -V ₁ ) / (I ₂ -I ₁ )

It is determined whether or not the calculated detection resistance value Rdet is within a range allowed by the IEEE 802.3af standard (step 110). For example, it is determined whether the value is within the range of 17 K? To 30 K ?. If the calculated detection resistance Rdet is a value within the range allowed by the IEEE 802.3af standard, the controller 20 determines that the PD 14 is a device conforming to the IEEE 802.3af standard (step 112). .

If the calculated detection resistance Rdet is outside the range allowed by the IEEE 802.3af standard, the controller 20 determines that the PD 14 is a legacy device powered by the PSE 12. . For example, when the PD 14 is a legacy device having a large capacitor C of 47 kHz or more, and is a diode coupled to the capacitor C continuously, the second measurement voltage V as a result of charging the large capacitor C is shown. ₂ ) may be greater than the first measurement voltage V ₁ . If the capacitor C is very large, the two measured voltages V ₁ and V ₂ can be approximately equal. The difference between the two measured voltages V ₁ and V ₂ will be limited to the offset voltage due to the forward drop for the successive diode.

If PD 14 has a smaller capacitor C (e.g., in the range of 1 ㎌ to 33 ㎌) and a resistor coupled in parallel to the capacitor C, the size of the capacitor C, the resistance of the resistor According to the value, the generation values of the detection currents I ₁ and I ₂ , and the measurement time period between the first measurement voltage V ₁ and the second measurement voltage V ₂ , the second measurement voltage V ₂ is determined by the first measurement. It may or may not be greater than the voltage V ₁ . However, as the capacitor is charged, using the difference between the first measurement voltage V ₁ and the second measurement voltage V ₂ by the offset voltage generated by the combination of the capacitor and the parallel resistor, the connected PD 14 is connected. May be identified as a legacy device.

Therefore, when the second measurement voltage V ₂ generated in response to the second detection current I ₂ , which is a value smaller than the first detection current I _{1, is} greater than the first measurement voltage V ₁ , the controller 20 is connected to the connected PD. 14 may be determined as a legacy device.

If the first measured voltage V ₁ is greater than the second measured voltage V ₂ , the controller 20 continuously detects I _1. And compares a predetermined threshold voltage corresponding to the offset voltage generated in response to I ₂ with a difference between the first measurement voltage V ₁ and the second measurement voltage V ₂ . When the difference between the first measurement voltage V ₁ and the second measurement voltage V ₂ is less than the threshold voltage, the controller 20 determines that the connected PD 14 is a legacy device.

According to one preferred embodiment of the present invention, if the detection resistance Rdet calculated in step 108 is outside the range defined by the IEEE 802.3af standard, the controller 20 may be connected to the legacy PD which may be connected to the PSE 12. In order to detect, the threshold resistance value R _th corresponding to the predetermined threshold voltage is compared with the detection resistance value (step 114). For example, the threshold resistance value R _th may be equal to 6 KΩ.

If the detection resistance Rdet is less than the threshold resistance R _th or is negative (indicating that the voltage V ₂ is greater than the voltage V ₁ ), the controller 20 may PSE the connected PD 14. It is determined that the legacy device is powered from 12 (step 116). If the detection resistance value Rdet is not negative or less than the threshold resistance value R _th , the controller 20 indicates that the connected PD 14 is not a PD conforming to the IEEE 802.3af standard, and the PSE 12 It is determined that the legacy PD is not powered from (step 118).

Thus, in addition to the first detection resistance range allowed by the IEEE 802.3af standard, the controller 20 also checks for a second predetermined detection resistance range to detect a legacy device that may be connected to the PSE 12. As described above, the second detection range may include, for example, negative values of the detection resistance value or values less than the predetermined threshold resistance value. When the detection resistance Rdet of the connected PD 14 is a value within the second range, the connected PD 14 is considered to be a legacy device. As a result, the PSE 12 can not only detect a powered PD conforming to the IEEE 802.3af standard, but also detect legacy devices requiring power supply.

The aspects of the invention have been illustrated and described in the foregoing description. In addition, the present invention illustrates and describes only preferred embodiments, but as described above, those skilled in the art will appreciate that various modifications may be made without departing from the scope of the present invention. Modifications and variations are possible.

The above-described embodiments describe preferred embodiments known in practicing the present invention, and those skilled in the art intend to use the invention in various modifications, including those or other embodiments required by the specific application or uses of the present invention. do.

Accordingly, the description is not intended to limit the invention to the forms described herein. In addition, the claims set forth below may be construed to include alternative embodiments.

Claims (19)

In a system for providing power to a powered device (PD) in a PoE system, A PD probe circuit for determining a PD response signal generated in response to a detection signal provided to the power device (PD); And In response to a detection value determined based on the PD response signal, when the detection value is within a predetermined first range, the power device PD is determined to be a device that satisfies a PoE standard, and the detection value is the second value. Control circuitry that determines the power device PD as a legacy PD device when present in a second predetermined range outside of one range. Including, The PD probe circuit is configured to generate a first detection current prior to a second detection current less than the first detection current. Power supply system. The method of claim 1, The control circuit is configured to determine whether the power device (PD) is a legacy device by comparing the detection value with a predetermined threshold detection value. The method of claim 1, The detection value includes a detection resistance value and the control circuit is configured to determine the power device (PD) as the legacy PD device when the detection resistance value is less than a predetermined threshold resistance value. The method of claim 1, The detection value includes a detection resistance value, and the control circuit is configured to determine that the power device (PD) is the legacy PD device when the detection resistance value is a negative value. delete The method of claim 1, And the control circuit is configured to detect the legacy PD device when the first response voltage generated in response to the first current is less than the second response voltage generated in response to the second current. The method of claim 1, The control circuit may be configured such that the first response voltage generated in response to the first current is greater than the second response voltage generated in response to the second current and the difference between the first response voltage and the second response voltage is less than a predetermined threshold value. If so, configured to detect the legacy PD device. The method of claim 1, The control circuit may select the legacy device when the detection resistance value defined according to the difference between the first response voltage generated in response to the first current and the second response voltage generated in response to the second current is less than a predetermined threshold resistance value. Power supply system configured to detect. 9. The method of claim 8, And the predetermined threshold resistance value is less than a minimum signature resistance value defined in accordance with the PoE standard. In a method for supplying power to a powered device (PD) in a PoE system, Generating a detection signal supplied to the power device (PD) to determine a PD response signal; And On the basis of the PD response signal, if the detection value is within a predetermined first range, the power device PD is determined to be a device satisfying a PoE standard, and the detection value is a predetermined first value outside the first range. Determining the power device PD as a legacy PD device when present in a range of two; Including, Generating the detection signal, Generating a first detection signal prior to a second detection signal smaller than the first detection signal Power supply method comprising a. delete The method of claim 10, The legacy device when a detection resistance value defined as a difference between a first response signal generated in response to the first detection signal and a second response signal generated in response to the second detection signal is less than a predetermined value; The power supply method in which is detected. The method of claim 12, And the predetermined value is less than a minimum signature resistance defined by the PoE standard. The method of claim 10, When a detection resistance value defined as a difference between a first response signal generated in response to the first detection signal and a second response signal generated in response to the second detection signal is a negative value And a power supply method in which the legacy device is detected. The method of claim 10, And the legacy PD device is detected when the first response signal generated in response to the first detection signal is smaller than the second response signal generated in response to the second detection signal. The method of claim 10, A threshold in which the first response signal generated in response to the first detection signal is greater than the second response signal generated in response to the second detection signal and a difference between the first response signal and the second response signal is preset; And if less than a preset threshold value, the legacy PD device is detected. In a power sourcing device (PSE) in a PoE system, The power device PD generates a first detection current supplied to the power device PD to determine a first response voltage, and generates a second detection current smaller than the first detection current to determine a second response voltage. A) detection source; And When the detection resistance defined as a result of subtracting the second response voltage from the first response voltage is smaller than a predetermined value smaller than the minimum signature resistance defined by the PoE standard, determining the power device PD as a legacy PD. Detection circuit Power sourcing device comprising a 18. The method of claim 17, And the legacy PD is detected when the detection resistance is negative. 18. The method of claim 17, And the detection circuitry is further configured to detect a power device (PD) that satisfies the requirements of the PoE standard when the detection resistance value is within a required signature resistance range.

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